A system for mounting a motor temperature sensor includes: a hairpin wound stator including a stator core having a plurality of slots, and a plurality of hairpins inserted into the slots of the stator core; and a motor temperature sensor including a sensor element and a sensor housing covering the sensor element, wherein the sensor housing is detachably fitted into one of the plurality of hairpins.

A control valve (2) for regulating a fluid flow in an HVAC comprises a valve body (21) and a temperature sensor (25) configured to measure the temperature of a fluid (24) flowing within the control valve (2). The temperature sensor (25) is arranged such that the temperature sensor (25) is essentially thermally decoupled from the valve body (21).

A disaster prevention apparatus includes: an outer cover 11; a thermistor 14 that detects a physical quantity of a detection target; a protective portion 12 that accommodates the thermistor 14, that is provided on the outer cover 11, and that has an opening portion 122 through which the detection target flows in and out with respect to the thermistor 14; and a prevention portion 13 that prevents a contact object from coming into contact with the thermistor 14, and that is provided in the opening portion 122, wherein the prevention portion 13 is a projection, and the prevention portion 13 protrudes from the outer cover 11 side, the prevention portion 13 is provided at a position close to a center of an edge portion of the opening portion 122, and an outer surface of the prevention portion 13 is curved.

A disaster prevention apparatus includes: an outer cover 11; a thermistor 14 that detects a physical quantity of a detection target; a protective portion 12 that accommodates the thermistor 14, that is provided on the outer cover 11, and that has an opening portion 122 through which the detection target flows in and out with respect to the thermistor 14; and a prevention portion 13 that prevents a contact object from coming into contact with the thermistor 14, and that is provided in the opening portion 122, wherein the prevention portion 13 is a projection, and the prevention portion 13 protrudes from the outer cover 11 side, the prevention portion 13 is provided at a position close to a center of an edge portion of the opening portion 122, and an outer surface of the prevention portion 13 is curved.

Disclosed are a single-pin wireless electronic thermometer and a charging device for the same. The single-pin wireless electronic thermometer includes a temperature measuring body with an inner cavity, and one end of the temperature measuring body is connected with an insertion part for inserting into food, a temperature sensor for detecting an internal temperature of the food is arranged inside at least the temperature measuring body or the insertion part, a temperature sensing portion of the temperature sensor is fitted to an inner wall of the temperature measuring body or an inner wall of the insertion part, and a control board is arranged in the inner cavity and connected to the temperature sensor. The single-pin wireless electronic thermometer of the present disclosure has a compact structure, with faster and more accurate heat conduction, so that the measuring effect may be improved.

Disclosed are a single-pin wireless electronic thermometer and a charging device for the same. The single-pin wireless electronic thermometer includes a temperature measuring body with an inner cavity, and one end of the temperature measuring body is connected with an insertion part for inserting into food, a temperature sensor for detecting an internal temperature of the food is arranged inside at least the temperature measuring body or the insertion part, a temperature sensing portion of the temperature sensor is fitted to an inner wall of the temperature measuring body or an inner wall of the insertion part, and a control board is arranged in the inner cavity and connected to the temperature sensor. The single-pin wireless electronic thermometer of the present disclosure has a compact structure, with faster and more accurate heat conduction, so that the measuring effect may be improved.

A domestic cooking appliance for heating a food item is provided. The domestic cooking appliance includes a housing; a cooking chamber located in the housing and having a wall, the cooking chamber being configured to contain the food item while the food item is being heated; a heating element that provides heat to the cooking chamber for heating the food item; a temperature detector located in the cooking chamber and configured to detect a temperature in the cooking chamber; and a temperature detector positive motion stop located in the cooking chamber and surrounding a portion of the temperature detector.

A temperature sensor of a thermal monitoring system is provided for use in power distribution systems. The temperature sensor comprises ceramic printed circuit board (PCB) and a terminal. The ceramic PCB includes a temperature sensing element disposed on a side of the ceramic PCB. The terminal is configured to be fixed directly in contact with a measured point and is directly in touch with the ceramic PCB such that heat is conducted from the terminal, through the ceramic PCB and then to the temperature sensing element. The temperature sensing element is configured to generate an electrical signal in response to the heat such that the electrical signal is sent through a pair of lead wires to a controller for monitoring a temperature. The temperature sensor further comprises an overmolded plastic material to seal a portion of the terminal, the ceramic PCB in its entirety and a portion of the pair of lead wires to ensure a desired physical strength and a desired dielectric strength.

A temperature sensor of a thermal monitoring system is provided for use in power distribution systems. The temperature sensor comprises ceramic printed circuit board (PCB) and a terminal. The ceramic PCB includes a temperature sensing element disposed on a side of the ceramic PCB. The terminal is configured to be fixed directly in contact with a measured point and is directly in touch with the ceramic PCB such that heat is conducted from the terminal, through the ceramic PCB and then to the temperature sensing element. The temperature sensing element is configured to generate an electrical signal in response to the heat such that the electrical signal is sent through a pair of lead wires to a controller for monitoring a temperature. The temperature sensor further comprises an overmolded plastic material to seal a portion of the terminal, the ceramic PCB in its entirety and a portion of the pair of lead wires to ensure a desired physical strength and a desired dielectric strength.

An assembly of a thermal probe and a probe fitting arranged to measure the temperature of a fluid medium flowing in a passage of the probe fitting. The assembly comprises a temperature sensing assembly that produces a resistance which varies with the temperature. A connector assembly that is connected to the temperature sensing assembly that transmits the resistance to external circuitry. A non-metallic housing includes a sensor portion incasing the temperature sensing assembly and a connector portion housing the connector assembly. A probe receptacle attached to the probe fitting is arranged to receive the sensor portion of the thermal probe, positioning the temperature sensing assembly in the passage to sense the temperature of the fluid medium flowing in the passage.