CN211696706U - Laboratory environment temperature detects transmission device - Google Patents

Abstract

The utility model relates to a laboratory ambient temperature detects transmission device, its characteristics lie in including left slide mechanism, right slide mechanism, middle slide mechanism, wire rope, temperature sensor, wherein left slide mechanism is about being with right slide mechanism and arranges side by side, wire rope's both ends are fixed respectively on left slide mechanism, right slide mechanism to make wire rope can be vertical reciprocating motion under left slide mechanism and right slide mechanism's drive, middle slide mechanism sliding suit is on wire rope, temperature sensor sets up on middle slide mechanism. The utility model discloses enable temperature sensor and remove at will to can satisfy the requirement of multiple spot measurement, and then help the experimenter to master fast, the accuracy whether temperature everywhere in the laboratory has reached the within range that needs, receive the influence of temperature with the accuracy of avoiding the experiment.

Description

Laboratory environment temperature detects transmission device

Technical Field

The utility model relates to a laboratory paraphernalia field, especially a laboratory ambient temperature detects transmission device.

Background

At present, when experiments are carried out in a laboratory, severe requirements are often imposed on the temperature. Strict temperature monitoring and control in the laboratory is required before the experiment can be performed. Wherein, the mode of current detection laboratory ambient temperature is temperature sensor in fixed mounting on certain position in the laboratory to detect the temperature in this position by temperature sensor, and pass through wire or wireless network or bluetooth transmission for the management center machine with the temperature data that detect, so that the experimenter observes the temperature in the laboratory through the management center machine. Because the temperature sensor is fixed, the temperature sensor can only detect the temperature at the fixed position, and whether the temperature in the whole laboratory is constant or not cannot be accurately judged. When the air temperature in the laboratory is uneven, the experimenter walks around in the laboratory, the temperature around experimental apparatus or the chemical reaction is easy to fluctuate, and therefore the accuracy of experimental data is easy to reduce greatly.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to solve above-mentioned problem and not enough, provide a laboratory ambient temperature detects transmission device, this laboratory ambient temperature detects transmission device enables temperature sensor and removes at will to can satisfy multiple spot measuring requirement, and then help the experimenter to master fast, accurately whether temperature everywhere in the laboratory has reached the within range that needs, receives the influence of temperature with the accuracy of avoiding the experiment.

The technical scheme of the utility model is realized like this:

the utility model provides a laboratory ambient temperature detects transmission device, its characteristics lie in including left slide mechanism, right slide mechanism, middle slide mechanism, wire rope, temperature sensor, and wherein left slide mechanism arranges side by side about being with right slide mechanism, wire rope's both ends are fixed respectively on left slide mechanism, right slide mechanism to make wire rope can be vertical reciprocating motion under left slide mechanism and right slide mechanism's drive, middle slide mechanism sliding sleeve is on wire rope, temperature sensor sets up on middle slide mechanism.

Preferably, the left sliding mechanism comprises a left positioning seat, a left guide rod, a left sliding clamping piece, a left driving motor and a left friction roller, the left guide rod is longitudinally arranged, the left surface of the left guide rod is connected with the left positioning seat, the left sliding clamping piece can be longitudinally slidably clamped on the left guide rod, a left abdicating hole penetrating through the top surface of the left guide rod is formed in the top surface of the left sliding clamping piece, the left driving motor is transversely arranged on the left sliding clamping piece, the left friction roller is in driving connection with the left driving motor, the lower part of the left friction roller penetrates through the left abdicating hole and then is pressed on the top surface of the left guide rod, and the rotating center line of the left friction roller is transversely extended; the right sliding mechanism comprises a right positioning seat, a right guide rod, a right sliding clamping piece, a right driving motor and a right friction roller, the right guide rod is longitudinally arranged, the right surface of the right guide rod is connected with the right positioning seat, the right sliding clamping piece can be longitudinally slidably clamped on the right guide rod, a right abdicating hole penetrating through the top surface of the right guide rod is formed in the top surface of the right sliding clamping piece, the right driving motor is transversely arranged on the right sliding clamping piece, the right friction roller is in driving connection with the right driving motor, the lower part of the right friction roller penetrates through the right abdicating hole and then is pressed on the top surface of the right guide rod, and the rotating central line of the right friction roller transversely extends; and two ends of the steel wire rope are respectively fixed on the left sliding clamping piece and the right sliding clamping piece.

Preferably, a left hanging ring is arranged on the right surface of the left slide clamping piece, a right hanging ring is arranged on the left surface of the right slide clamping piece, and two ends of the steel wire rope are respectively penetrated and bound on the left hanging ring and the right hanging ring.

Preferably, the intermediate sliding mechanism comprises a sliding part, a first motor, a second motor, a first friction roller and a second friction roller, the sliding part is provided with a through hole which penetrates through the sliding part transversely, the sliding part is sleeved on the steel wire rope in a sliding way through the through hole, the first motor is longitudinally arranged on the sliding part, the first friction roller is in driving connection with the first motor, the first friction roller is positioned above the steel wire rope, the first friction roller is pressed on the top of the steel wire rope, the second motor is longitudinally arranged on the sliding part, the second friction roller is in driving connection with the second motor, the second friction roller is positioned below the steel wire rope, the second friction roller is positioned right below the first friction roller, and pressing the second friction roller on the bottom of the steel wire rope, wherein the temperature sensor is arranged on the bottom surface of the sliding part.

Preferably, the outer surface of the steel wire rope is provided with a limiting convex strip, the length direction of the limiting convex strip is enabled to be the same as that of the steel wire rope, a transversely extending limiting clamping groove is formed in the hole wall of the sleeve penetrating hole, and the limiting clamping groove is slidably clamped on the limiting convex strip.

Preferably, the laboratory ambient temperature detection and transmission device further comprises a metal sleeve, the metal sleeve is transversely embedded on the sliding part, an inner hole of the metal sleeve forms a sleeve penetrating hole, and the limiting clamping groove is formed in the hole wall of the inner hole of the metal sleeve.

The utility model has the advantages that: the laboratory environment temperature detection and transmission device comprises a left sliding mechanism, a right sliding mechanism, a middle sliding mechanism, a steel wire rope and a temperature sensor, wherein the steel wire rope can be driven to do longitudinal reciprocating motion through the left sliding mechanism and the right sliding mechanism, and the temperature sensor can be driven to do left-right reciprocating motion on the steel wire rope through the middle sliding mechanism; therefore, when the left sliding mechanism and the right sliding mechanism are respectively fixed on the left wall and the right wall of a laboratory, the steel wire rope can do longitudinal reciprocating motion in the laboratory, and the temperature sensor can do front-back reciprocating motion; when the middle sliding mechanism slides on the steel wire rope, the temperature sensor can do transverse reciprocating motion; temperature sensor just can remove at will like this, and this just can measure the temperature of a plurality of positions in the laboratory through temperature sensor, can satisfy multiple spot measurement's requirement promptly, and this can help the experimenter to master fast, the accuracy whether everywhere temperature has reached the within range that needs in the laboratory to the accuracy of avoiding the experiment receives the influence of temperature, and then can improve the accuracy of experiment greatly.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic structural view of the middle left sliding mechanism of the present invention.

Fig. 3 is a schematic structural view of the middle-right sliding mechanism of the present invention.

Fig. 4 is a schematic view of the sectional structure of the main view direction of the middle sliding mechanism of the present invention.

Fig. 5 is a schematic view of the sectional structure of the middle sliding mechanism in the left-hand direction.

Fig. 6 is a schematic structural view of the metal sleeve according to the present invention.

Fig. 7 is a schematic cross-sectional structure diagram of the steel wire rope of the present invention.

Detailed Description

As shown in fig. 1, a laboratory environment temperature detects transmission device, including left slide mechanism 1, right slide mechanism 2, middle slide mechanism 3, wire rope 4, temperature sensor 5, wherein arrange side by side about left slide mechanism 1 is with right slide mechanism 2, wire rope 4's both ends are fixed respectively on left slide mechanism 1, right slide mechanism 2 to make wire rope 4 can be vertical reciprocating motion under left slide mechanism 1 and right slide mechanism 2's drive, middle slide mechanism 3 slip suit is on wire rope 4, temperature sensor 5 sets up on middle slide mechanism 3. The laboratory environment temperature detection and transmission device comprises a left sliding mechanism 1, a right sliding mechanism 2, a middle sliding mechanism 3, a steel wire rope 4 and a temperature sensor 5, wherein the steel wire rope 4 can be driven to do longitudinal reciprocating motion through the left sliding mechanism 1 and the right sliding mechanism 2, and the temperature sensor 5 can be driven to do left-right reciprocating motion on the steel wire rope 4 through the middle sliding mechanism 3; therefore, when the left sliding mechanism 1 and the right sliding mechanism 2 are respectively fixed on the left wall and the right wall of a laboratory, the steel wire rope 4 can do longitudinal reciprocating motion in the laboratory, and the temperature sensor 5 can also do front-back reciprocating motion; when the intermediate sliding mechanism 3 slides on the steel wire rope 4, the temperature sensor 5 can do transverse reciprocating motion; temperature sensor 5 just can remove at will like this, and this just can measure the temperature of a plurality of positions in the laboratory through temperature sensor 5, can satisfy multiple spot measurement's requirement promptly, and this can help the experimenter to master fast, the accuracy whether temperature everywhere in the laboratory has reached the within range that needs to the accuracy of avoiding the experiment receives the influence of temperature, and then can improve the accuracy of experiment greatly.

When the laboratory environment temperature detection transmission device is used, the left sliding mechanism 1 and the right sliding mechanism 2 are respectively fixed on opposite walls in a laboratory, so that the temperature sensor 5 can be erected in the laboratory. Therefore, the temperature sensor 5 can be driven to longitudinally reciprocate through the sliding of the left sliding mechanism 1 and the right sliding mechanism 2, and the temperature sensor 5 can transversely reciprocate through the middle sliding mechanism 3, so that the purpose of accurately measuring the temperature of each part of a laboratory can be met.

As shown in fig. 1 to 3, the left sliding mechanism 1 includes a left positioning seat 11, a left guide rod 12, a left sliding fastener 13, a left driving motor 14, and a left friction roller 15, wherein the left guide rod 12 is longitudinally arranged, and the left surface of the left guide rod 12 is connected to the left positioning seat 11, the left sliding fastener 13 is longitudinally slidably fastened to the left guide rod 12, a left abdicating hole 131 penetrating through the top surface of the left guide rod 12 is formed in the top surface of the left sliding fastener 13, the left driving motor 14 is transversely disposed on the left sliding fastener 13, the left friction roller 15 is drivingly connected to the left driving motor 14, and the lower portion of the left friction roller 15 passes through the left abdicating hole 131 and then presses on the top surface of the left guide rod 12, and the rotation center line of the left friction roller 15 also transversely extends; the right sliding mechanism 2 comprises a right positioning seat 21, a right guide rod 22, a right sliding clamping piece 23, a right driving motor 24 and a right friction roller 25, wherein the right guide rod 22 is longitudinally arranged, the right surface of the right guide rod 22 is connected with the right positioning seat 21, the right sliding clamping piece 23 can be longitudinally slidably clamped on the right guide rod 22, a right abdicating hole 231 penetrating through the top surface of the right guide rod 22 is formed in the top surface of the right sliding clamping piece 23, the right driving motor 24 is transversely arranged on the right sliding clamping piece 23, the right friction roller 25 is in driving connection with the right driving motor 24, the lower part of the right friction roller 25 penetrates through the right abdicating hole 231 and then is pressed on the top surface of the right guide rod 22, and the rotation center line of the right friction roller 25 also transversely extends; the two ends of the steel wire rope 4 are respectively fixed on the left slide clamping piece 13 and the right slide clamping piece 23. The structural design of the left sliding mechanism 1 and the right sliding mechanism 2 is very simple and reliable, and the convenience and the reliability of manufacturing of the laboratory environment temperature detection transmission device are improved.

In the actual manufacturing process, a plurality of left positioning seats 11 can be longitudinally arranged side by side to position and support the left guide rod 12; similarly, a plurality of right positioning seats 21 can be longitudinally arranged side by side to position and support the right guide rod 22; this contributes to improvement in the reliability of the mounting and positioning of the left and right guide bars 12, 22.

As shown in fig. 2 and fig. 3, the left positioning seat 11 and the right positioning seat 21 are both provided with through holes 10 that penetrate longitudinally, and the through holes 10 can be used for screws to penetrate, so that the left positioning seat 11 and the right positioning seat 21 can be fixed on the wall by the screws.

Through making left friction roller 15 be located the top of left guide bar 12, receive the effect of gravity at left slide card dress spare 13 and left driving motor 14 like this, enable left friction roller 15 and sticis on left guide bar 12, just so can make the frictional force between left friction roller 15 and the left guide bar 12 enough big to satisfy the slip demand of left slide card dress spare 13.

In the actual production process, the left friction roller 15 can be replaced by a gear, and a rack or a rack portion arranged longitudinally is provided on the top surface of the left guide bar 12, and the gear is engaged with the rack, so that the sliding requirement of the left slide fastener 13 can be met.

By positioning the right friction roller 25 above the right guide bar 22, the right friction roller 25 can be pressed against the right guide bar 22 under the action of gravity on the right slide fastener 23 and the right drive motor 24, so that the friction force between the right friction roller 25 and the right guide bar 22 is large enough to meet the sliding requirement of the right slide fastener 23.

In the actual production process, the right friction roller 25 can be replaced by a gear, and a rack or a rack part which is longitudinally arranged is arranged on the top surface of the right guide rod 22, and the gear is meshed with the rack, so that the sliding requirement of the right slide clamping piece 23 can be met.

The left driving motor 14 is powered by a first storage battery arranged on the left slide fastener 13, a first wireless signal receiver and a first control circuit module are arranged on the left slide fastener 13, and the first storage battery, the first wireless signal receiver and the left driving motor 14 are all electrically connected with the first control circuit module. The right driving motor 24 is powered by a second storage battery arranged on the right slide clamping piece 23, a second wireless signal receiver and a second control circuit module are arranged on the right slide clamping piece 23, and the second storage battery, the second wireless signal receiver and the right driving motor 24 are all electrically connected with the second control circuit module. The first wireless signal receiver and the second wireless signal receiver simultaneously receive the wireless signals sent by the remote controller and act, so that the requirement of synchronous action of the left driving motor 14 and the right driving motor 24 is met, and the requirement of stable longitudinal movement of the steel wire rope 4 can be met.

Wherein, the control of the left driving motor 14 is completed on the left sliding mechanism 1 through a control circuit and a wireless receiving module on the existing remote control automobile; this can satisfy the forward and reverse rotation requirements of the left drive motor 14, and thus the forward and backward movement requirements of the left slide attachment 13.

Wherein, the right sliding mechanism 2 controls the right driving motor 24 through a control circuit and a wireless receiving module on the existing remote control automobile; this can satisfy the forward and reverse rotation requirements of the right drive motor 24, and thus can satisfy the forward and backward movement requirements of the right slide card unit 23.

The left positioning seat 11, the left guide rod 12 and the left slide fastener 13 are all made of stainless steel, and the left friction roller 15 is made of soft plastic, so that when the left friction roller 15 is pressed on the left guide rod 12, friction force can be effectively improved through deformation of the left friction roller, and the sliding accuracy of the left slide fastener 13 is improved.

The right positioning seat 21, the right guide rod 22 and the right slide clamping piece 23 are all made of stainless steel, the right friction roller 25 is made of soft plastic, and therefore when the right friction roller 25 is pressed on the right guide rod 22, friction force can be effectively improved through deformation of the right friction roller 25, and accuracy of sliding of the right slide clamping piece 23 is improved.

The left friction roller 15 and the right friction roller 25 are made of silicon rubber, ethylene propylene diene monomer or nitrile rubber.

As shown in fig. 1 to 3, a left hanging ring 132 is disposed on the right surface of the left slide fastener 13, a right hanging ring 232 is disposed on the left surface of the right slide fastener 23, and two ends of the wire rope 4 are respectively inserted and bound to the left hanging ring 132 and the right hanging ring 232. Through the setting of left rings 132 and right rings 232, help improving convenience and the reliability that wire rope 4 binded to help improving convenience and the reliability that laboratory ambient temperature detected the transmission device equipment.

As shown in fig. 1, 4 and 5, the intermediate sliding mechanism 3 includes a sliding member 31, a first motor 32, a second motor 33, a first friction roller 34 and a second friction roller 35, wherein the sliding member 31 is provided with a through hole 311 that penetrates transversely, the sliding member 31 is slidably sleeved on the steel wire rope 4 through the through hole 311, the first motor 32 is longitudinally arranged on the sliding member 31, the first friction roller 34 is in driving connection with the first motor 32, the first friction roller 34 is positioned above the steel wire rope 4, the first friction roller 34 is pressed on the top of the steel wire rope 4, the second motor 33 is longitudinally arranged on the sliding member 31, the second friction roller 35 is in driving connection with the second motor 33, the second friction roller 35 is positioned below the steel wire rope 4, and the second friction roller 35 is positioned right below the first friction roller 34, and the second friction roller 35 is pressed against the bottom of the wire rope 4, and the temperature sensor 5 is provided on the bottom surface of the slider 31. This intermediate sliding mechanism 3's overall structure is very simple reliable, and through making first friction gyro wheel 34 and second friction gyro wheel 35 press from both sides respectively in wire rope 4 upper and lower both sides, can play tight effect to wire rope 4 like this to make intermediate sliding mechanism 3 can hug closely on wire rope 4 reliably, thereby help improving the gliding stability of intermediate sliding mechanism 3, avoid appearing the condition of skidding, and then help improving laboratory ambient temperature and detect transmission device's reliability.

The sliding member 31 is respectively provided with a third storage battery, a third wireless signal receiving module and a third control circuit module, and the first motor 32, the second motor 33, the third storage battery and the third wireless signal receiving module are all electrically connected with the third control circuit module. The third wireless signal receiver is operated after receiving the wireless signal sent by the remote controller, so as to meet the requirement of synchronous operation of the first motor 32 and the second motor 33, and thus the requirement of transverse movement of the middle sliding mechanism 3 can be met.

Wherein the directions of rotation of the first motor 32 and the second motor 33 are opposite, so that the sliding requirement of the sliding member 31 can be met.

The third wireless signal receiving module and the third control circuit module adopt a control circuit on the existing toy car, so that the square rotation requirements of the first motor 32 and the second motor 33 can be met, and the requirement of the middle sliding mechanism 3 for transverse movement can be met.

Wherein, temperature sensor 5 is through setting up the fourth battery power supply on slider 31, and still is equipped with wireless signal transceiver module on slider 31, wireless signal transceiver module, temperature sensor 5 all are connected with the fourth battery looks electricity, the temperature data that temperature sensor 5 detected pass through wireless signal transceiver module and transmit the management center machine to the laboratory staff learns laboratory temperature everywhere through the management center machine.

The laboratory environment temperature detection and transmission device is characterized in that each electrical element in the laboratory environment temperature detection and transmission device is powered by a storage battery, and related data signals are transmitted by Bluetooth or a wireless network or ultrasonic waves. Thus, synchronous control and temperature data transmission to the management center can be realized.

The sliding member 31 is made of stainless steel, and the first friction roller 34 and the second friction roller 35 are both made of soft plastic, so that when the first friction roller 34 and the second friction roller 35 are pressed on the steel wire rope 4, the friction force can be effectively improved through the deformation of the first friction roller 34 and the second friction roller 35, and the sliding accuracy of the sliding member 31 can be improved.

The first friction roller 34 and the second friction roller 35 are made of silicon rubber, ethylene propylene diene monomer or nitrile rubber.

As shown in fig. 4 to 7, a limiting protrusion 41 is disposed on an outer surface of the steel wire rope 4, a length direction of the limiting protrusion 41 is the same as a length direction of the steel wire rope 4, a transversely extending limiting slot 312 is disposed on a hole wall of the sleeve hole 311, and the limiting slot 312 is slidably engaged with the limiting protrusion 41. Through the cooperation of spacing sand grip 41 and spacing draw-in groove 312, can avoid slider 31 to rotate on wire rope 4 to help improving the accuracy of slider 31 location, and then help improving middle slide mechanism 3's reliability.

The limiting convex strip 41 is a steel wire strip welded on the surface of the steel wire rope 4. Such a structure is very simple and very easy to implement.

As shown in fig. 4 to 6, the laboratory environment temperature detection and transmission device further includes a metal sleeve 6, the metal sleeve 6 is transversely embedded on the sliding member 31, an inner hole of the metal sleeve 6 forms a sleeve hole 311, and the limiting clamping groove 312 is formed on a hole wall of the inner hole of the metal sleeve 6. By adopting the metal sleeve 6, the sliding requirement can be met, and the abrasion resistance of the contact part of the metal sleeve and the steel wire rope 4 can be improved, so that the service life of the middle sliding mechanism 3 is prolonged. Wherein, after the metal sleeve 6 is used, the sliding member 31 can be made of plastic, which helps to reduce the convenience of manufacturing the intermediate sliding mechanism 3.

The metal sleeve 6 is made of stainless steel; this helps to improve the service life.

Claims (6)

1. The utility model provides a laboratory environment temperature detects transmission device which characterized in that: including left slide mechanism (1), right slide mechanism (2), middle slide mechanism (3), wire rope (4), temperature sensor (5), wherein left slide mechanism (1) is about being with right slide mechanism (2) and arranges side by side, the both ends of wire rope (4) are fixed respectively on left slide mechanism (1), right slide mechanism (2) to make wire rope (4) can be vertical reciprocating motion under the drive of left slide mechanism (1) and right slide mechanism (2), middle slide mechanism (3) slip suit is on wire rope (4), temperature sensor (5) set up in the middle on slide mechanism (3).

2. The laboratory ambient temperature detection conveyor of claim 1, wherein: the left sliding mechanism (1) comprises a left positioning seat (11), a left guide rod (12), a left sliding clamping piece (13), a left driving motor (14) and a left friction roller (15), the left guide rod (12) is longitudinally arranged, the left surface of the left guide rod (12) is connected with the left positioning seat (11), the left sliding clamping piece (13) can be longitudinally and slidably clamped on the left guide rod (12), a left abdicating hole (131) which penetrates through the top surface of the left guide rod (12) is arranged on the top surface of the left slide clamping piece (13), the left driving motor (14) is transversely arranged on the left sliding clamping piece (13), the left friction roller (15) is in driving connection with a left driving motor (14), the lower part of the left friction roller (15) passes through the left abdicating hole (131) and then is pressed on the top surface of the left guide rod (12), and the rotating center line of the left friction roller (15) extends transversely; the right sliding mechanism (2) comprises a right positioning seat (21), a right guide rod (22), a right sliding clamping piece (23), a right driving motor (24) and a right friction roller (25), the right guide rod (22) is longitudinally arranged, the right surface of the right guide rod (22) is connected with the right positioning seat (21), the right sliding clamping piece (23) can be longitudinally and slidably clamped on the right guide rod (22), a right abdicating hole (231) which penetrates through the top surface of the right guide rod (22) is arranged on the top surface of the right slide clamping piece (23), the right driving motor (24) is transversely arranged on the right sliding clamping piece (23), the right friction roller (25) is in driving connection with a right driving motor (24), the lower part of the right friction roller (25) passes through the right abdicating hole (231) and then is pressed on the top surface of the right guide rod (22), and the rotating center line of the right friction roller (25) extends transversely; and two ends of the steel wire rope (4) are respectively fixed on the left slide clamping piece (13) and the right slide clamping piece (23).

3. The laboratory ambient temperature detection conveyor of claim 2, wherein: the left surface of the left sliding clamping piece (13) is provided with a left hanging ring (132), the left surface of the right sliding clamping piece (23) is provided with a right hanging ring (232), and two ends of the steel wire rope (4) penetrate through and are tied on the left hanging ring (132) and the right hanging ring (232) respectively.

4. The laboratory ambient temperature detection conveyor of claim 1, wherein: the middle sliding mechanism (3) comprises a sliding part (31), a first motor (32), a second motor (33), a first friction roller (34) and a second friction roller (35), wherein a penetrating hole (311) which transversely penetrates through the sliding part (31) is formed in the sliding part (31), the sliding part (31) is sleeved on the steel wire rope (4) in a sliding mode through the penetrating hole (311), the first motor (32) is longitudinally arranged on the sliding part (31), the first friction roller (34) is connected with the first motor (32) in a driving mode, the first friction roller (34) is located above the steel wire rope (4), the first friction roller (34) is pressed on the top of the steel wire rope (4), the second motor (33) is longitudinally arranged on the sliding part (31), the second friction roller (35) is connected with the second motor (33) in a driving mode, and the second friction roller (35) is located below the steel wire rope (4), and a second friction roller (35) is positioned right below the first friction roller (34), the second friction roller (35) is pressed on the bottom of the steel wire rope (4), and the temperature sensor (5) is arranged on the bottom surface of the sliding part (31).

5. The laboratory ambient temperature detection and transmission device of claim 4, wherein: the outer surface of the steel wire rope (4) is provided with a limiting convex strip (41), the length direction of the limiting convex strip (41) is the same as that of the steel wire rope (4), the hole wall of the sleeve penetrating hole (311) is provided with a transversely extending limiting clamping groove (312), and the limiting clamping groove (312) is slidably clamped on the limiting convex strip (41).

6. The laboratory ambient temperature detection conveyor of claim 5, wherein: the metal sleeve is characterized by further comprising a metal sleeve (6), the metal sleeve (6) is transversely embedded on the sliding part (31), an inner hole of the metal sleeve (6) forms a sleeve penetrating hole (311), and the limiting clamping groove (312) is formed in the wall of the inner hole of the metal sleeve (6).

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